Ether Rhodamines with Enhanced Hydrophilicity, Fluorogenicity, and Brightness for Super-Resolution Imaging
Xiangning Fang, Qinglong Qiao, Zhifeng Li, Hao-Kai Li, Yalin Huang, Dongjie Hou, Jie Chen, Ning Xu, Kai An, Wenchao Jiang, Tao Yi, Pengjun Bao, Yinchan Zhang, Zhimin Wu, Xiaogang Liu, Zhaochao Xu
Abstract
Rhodamine dyes are widely used fluorophores in super-resolution fluorescence imaging due to their exceptional optical properties and “aggregation-disaggregation” induced fluorogenic activation. However, their excessive lipophilicity often reduces brightness in aqueous environments and causes off-target staining, limiting their effectiveness in high-resolution imaging. To address these challenges, we introduce an ether-decorated N-terminal modification strategy for rhodamine and silicon-rhodamine (Si-rhodamine), replacing conventional N -alkyl groups. The ether chains enhance water solubility, decrease aggregate size, and improve fluorogenicity across a wide concentration range. Their flexible, hydrophilic structure forms a protective shield around the xanthene core, minimizing dye-water interactions and reducing fluorescence quenching. Additionally, the inductive effect of the ether chains decreases the electron-donating strength of the amino groups, suppressing quenching caused by twisted intramolecular charge transfer (TICT). These modifications collectively increase the quantum yields of ER and ESiR in water from 0.35 and 0.19 (for tetraethyl-substituted analogs) to 0.70 and 0.41, respectively. Probes derived from ER and ESiR exhibit outstanding fluorogenicity, enhanced signal-to-noise ratios, and improved resolution in complex aqueous environments, demonstrating superior performance in advanced super-resolution imaging techniques such as structured illumination microscopy (SIM), stimulated emission depletion (STED) microscopy, and single molecule localization microscopy (SMLM). This work introduces a rational fluorophore design strategy that enhances aqueous brightness, minimizes nonspecific staining, and enables high-contrast, high-resolution imaging across multiple super-resolution modalities.